Light-field camera and method using wafer-level integration process

1. A camera module comprising at least one light-field camera and at least one high resolution camera, the at least one light-field camera having a multiple-lens array positioned above a light-field camera image sensor; wherein the light-field camera comprises at least a first lens element above the light-field camera image sensor at a same level as a first lens element of the high resolution camera above a high resolution camera image sensor; the first lens of the light-field camera and the first lens of the high resolution camera having deposited thereon an opaque aperture material having an aperture opening formed therein; and the multiple-lens array of the light-field camera being at a second distance above the light-field camera image sensor at a same level as a flat transparent plate of the high resolution camera.

2. The camera module of claim 1 wherein the light-field camera further comprises a second lens element at a third distance above the light-field camera image sensor at a same level as a second lens element of the high resolution camera distance above the high resolution camera image sensor.

3. The camera module of claim 1 wherein the light-field camera and high resolution camera are packaged in a same ball grid array package.

4. The camera module of claim 1 wherein aperture opening of the opaque material deposited on the first lens element of the light-field camera has a different size than the aperture opening of the opaque material deposited on the first lens element of the high resolution camera.

5. The camera module of claim 1 wherein there are four cameras in the camera module.

6. The camera module of claim 5 wherein the camera module comprises a first high resolution camera having a first focus distance and a second high resolution camera having a second focus distance.

7. A method of forming a camera module comprising at least one light-field camera and at least one high resolution camera comprising: forming a rectangular array of light-field camera and high resolution lens cubes simultaneously by bonding molded lens plates and spacer plates, the lens plates and spacer plates comprising: an upper lens plate having upper light-field camera lens elements and upper high resolution camera lens elements; a layer of opaque aperture material, selected from the group consisting of a metal and a black photoresist, being deposited on the upper lens plate with upper light-field aperture openings and upper high resolution camera aperture openings formed in the opaque aperture material; a first spacer plate disposed adjacent a bottom of the upper lens plate; a microlens plate bearing an array of multiple microlenses in the area of the at least one light-field camera, the microlens plate being flat, transparent, and treated with antireflective coatings in areas of the at least one high resolution camera; and a second spacer plate attached to a bottom of the microlens plate; and bonding at least at least one light-field camera lens cube and at least one high resolution lens cube as formed in the rectangular array of lens cubes to image sensors attached to a same integrated circuit package.

8. The method of claim 7 wherein the lens plates and spacer plates further comprise: a transparent aperture plate having a layer of opaque material deposited thereon with aperture openings for the at least one light-field and at least one high resolution cameras, and a third spacer plate attached to a bottom of the aperture plate.

9. The method of claim 8 wherein the lens plates and spacer plates further comprise a second lens plate with light-field camera lower lens elements and high resolution camera elements formed thereon, and a fourth spacer plate attached to a bottom of the second lens plate.

10. The method of claim 9 further comprising cutting a trench between cameras and filling the trench with an opaque material.